ES1179734U - Mechanical lock of high security, with hidden and inaccessible reading system, driven by linear movement and 90¿ turn, with automatic reset and closing (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

High security mechanical lock characterized in that it comprises a hidden and inaccessible reading system, activated by linear movement and a quarter turn, with automatic reset and closing. (Machine-translation by Google Translate, not legally binding)

Description

High security mechanical lock, with hidden and inaccessible reading system, actuated by linear movement and 90º rotation, with automatic reset and closing.

High security lock activated by a combination of a linear movement and a quarter turn, which does not incorporate any system of cylinders, bulbs or Borjas. The system consists of two main bodies (10 and 21), as shown in figure 1, a special key (9) and the system comprising the set of parts that make up the lock. By introducing the key and by combining a linear movement with another rotary, the different mechanical actions that allow the lock to be unlocked are triggered, in such a way that the linear limitation of the key at a specific point in the system allows you to turn a plunger of reading defined by holes that determine the correct position to release the readers of the system (16), which will be calibrated together with some lateral notches presented by the special key (9), said notches define the correct displacement of each reader producing a combination, which will release the mechanisms that allow the opening. It is especially applicable in recessed locks for all door configurations.

D E S C R I P C I Ó N 25

 OBJECT OF THE INVENTION

The present invention relates to a high security mechanical seal operated by the combination of a linear and rotary movement with a quarter turn, operable by means of a special key which defines a longitudinal point that makes it possible to rotate a plunger. which, faced in the correct position and associated with the notches of the key itself, makes it possible for the readers that give rise to the mechanism that 35

It allows the opening of the system, not incorporating cylinders, bulbs or Borjas. This system can be used in conventional doors, making it an inviolable lock system by traditionally used means, since such handling methods are useless and ineffective for the violation and opening of the lock, thus providing it with a very high security level. This system can also be used for any type of locks, such as garage access doors, shutters, security locks, etc., in short, everything that involves the use of a security lock.

 BACKGROUND OF THE INVENTION

At present, the different types of locks and locking or locking systems use shapes and models of light bulbs, cylinders or Borjas, which makes them vulnerable to the current methods and means of violation and manipulation, leading to a low level of security.

The problem with conventional locks systems is that 20 are well known and no longer offer security against the methods and / or techniques of violation that are being used today. This type of locks is far from the one presented by this document because, the proposal uses a new system of hidden mechanical readers, which are operable by means of a key for its opening, although keys with teeth like those traditionally used are not used, if not that it is a flat key that has several notches in one of its lateral faces, as well as a longitudinal recess which offers us an exact position of the plunger and that, in this way also allows the drag 30 of said plunger allowing this turn a quarter of a turn, by means of internal stops of the system, thus defining the correct angular position, which together with the longitudinal position defined by the key, allows the plunger in the location 35 to be combined in both locations

correct reading, making it possible for hidden internal readers to move to the position defined by the side notches of the key and thus releasing the mechanism that allows the system to open. It is therefore not necessary to turn the key more than a quarter turn to activate the unlocking of the lock, quite the opposite of how existing commercial locks do.

Current mechanical-type locks systems that incorporate cylinders, bulbs or drills (with sawtooth or point wrenches), and including those of security and armored doors 10, have ceased to offer the desired security as a consequence of the existence of methods and techniques of violation, which represent an obvious risk of suffering unwanted access, violence, robbery or theft.

On the other hand, we have systems that use new technologies, 15 such as electrical systems or electronic identification reader, with hidden lock system, systems that do not use light bulbs or cylinders. The problem that this type of lock can present is that they are vulnerable to other rape or vandalism systems, such as frequency sensors, or the use of decoder electronic systems, among others, which, finally, with the use of new technologies allow the violation of the system getting, simply, the opening of the system.

The advantages of the system presented compared to the existing ones is that 25 is fully mechanical and therefore invulnerable through the use of new technologies, electrical, electronic, frequency systems, or the application of programs or software or other techniques.

On the other hand, the system uses an innovative and 30 different operation from the traditional ones used by traditional locks, without cylinders, light bulbs or borjas, which gives it a unique level of security, making it invulnerable or inviolable through existing methods. .

 35

DESCRIPTION OF THE INVENTION

 With the purpose of achieving the objectives and avoiding the inconveniences described in the previous point, fundamentally those related to security and its violation, the invention 5 proposes a totally mechanical system for locking and opening the lock, which avoids any vandalism or breach by the methods and techniques known at present, thus ensuring that the system is exempt from them, especially since they lack mechanisms such as 10 cylinders, light bulbs or borjas, since it replaces said traditional systems with a set of hidden readers, usually in the number of three, (one to four) (minimum one, maximum defined by the available space) that act as a means of anterior locking and a fourth also hidden that acts as a means of posterior blocking 15 if the correct key is not inserted, which are operated by a special key, allowing to release the mechanism that causes unlocking and ape rtura of the lock. This lock system uses an innovative mechanism which is free of cylinders, light bulbs or bushes and it is not necessary to turn the key one or more turns to unlock the locks, just a simple linear movement of the key combined with a quarter turn of the same. The mechanism is made up of hidden notch readers that face the correct key and that allow them to move to a certain point by the same key, 25 this becomes possible when we introduce the flat key that has several notches in one of its lateral faces, as well as a longitudinal recess which offers us an exact position of the plunger and which, in this way, allows the drag of said plunger allowing it to rotate a quarter turn, by means of internal stops of the system, defining in this way the correct angular position, which together with the longitudinal position defined by the key, allows the combination of both locations to be able to face the plunger in the correct reading location, making it possible for hidden readers 35

internal can move to the position defined by the lateral notches of the key and thus releasing the retention system which, by means of the force applied by a torsion spring, allows the rotation of said cylinder, making opening movements possible breaking the security with the unlocking 5 of the opening and closing bolts, which are displaced by the rotation of the cylinder. Unlocking occurs when the hidden readers, actuated by aligning the holes of the reading plunger with the readers, are perfectly aligned with the cylinder which in turn unlocks the locking bolts of 10 opening and closing.

 In these locks, its main characteristic is that the readers of the key are inaccessible from the outside, along with its way of acting since, it is only necessary to insert the key, push it to the bottom and turn it a quarter of a turn being 15 of entering the second key and turning it, and, with a simple push the door will be open, while the closing of the door is completely automatic.

DESCRIPTION OF THE DRAWINGS 20

To complement the description that will then be made and in order to help a better understanding of the features of the invention, according to a preferred example of practical implementation thereof, an integral set of said description is attached, a set of planes where, for illustrative and non-limiting purposes, the following has been represented:

Figure 1 - Shows an overview of the device of the invention. 30

Figure 2 - Shows an overview of the device of the invention.

Figure 3 - Shows an isometric view of the main bodies, key and exploded set of device elements.

Figure 4 - Shows a detailed view of the key. 35

Figure 5 - Shows an isometric view of the main body of the invention device and its hidden readers.

Figure 6 - Shows an isometric view of the main and secondary body of the device of invention and the union of both.

Figure 7 - Shows an isometric view of the main and secondary body of the invention device and its rearmament.

Figure 8 - Shows an isometric view of the main and secondary body together with the secondary cylinder.

Figure 9 - Shows a general isometric view detailing the manual release actuation system of the locking bolt 10.

Figure 10 - Shows a general isometric detail view of the pivot system.

Figure 11 - Shows a general isometric detail view of the reset system. fifteen

Figure 12 - Shows a general isometric detail view of the reset system.

Figure 13 - Shows a general isometric detail view of the locking latch system.

Figure 14 - Shows a general isometric detail view of the locking latch system.

Figure 15 - Shows a general isometric detail view of the lock body.

Figure 16 - Shows a general isometric detail view of the lock body. 25

Figure 17 - Shows a general isometric detail view of the lock body.

Figure 18 - Shows a general isometric detail view of the ratchet system.

Figure 19 - Shows a general isometric detail view of the slip system.

Figure 20 - Shows a general isometric view of detail of the body closure cap.

Figure 21 - Shows a general isometric view of detail of the internal manual opening system. 35

Figure 22 - Shows a general isometric view of detail of the clearance compensation system.

Figure 23 - Shows a general isometric detail view of the exterior trim system and stops.

Figure 24 - Shows a general isometric view of detail of the mechanism with open door.

Figure 25 - Shows a general isometric detail view of the closed door mechanism.

Figure 26 - Shows a general isometric detail view of the mechanism with the key inserted and turned. 10

PREFERRED EMBODIMENT OF THE INVENTION

As can be seen in figures 1 to 2, the mechanical locking and opening system without locks or cylinders, can be operated by special key with linear movement combined with a quarter turn, object of the invention, in its preferred embodiment, comprises two main bodies (10 and 21). As shown in Figure 3, a special key (9) and the system comprising the set of parts that make up the lock, 20 explained by step below, whose parts are made of steel, although others can be used Materials of similar characteristics. As noted above, the action of the parts, as a preferred embodiment of the invention, is as follows:

On the one hand if we look at figures 3, we have the main body of the lock (10) which has mounted on the one hand the rearmament and actuation lock of the readers (12) next to its spring (11), by the opposite and opposite side we have mounted the 30 key hole lock bolt (3) next to its spring (4). In the central part of the body (10) we house the main cylinder (2), next to its torsion spring (1) and block said parts by means of the pin (5), we introduce the bolt (6) in the main cylinder ( 2), in order to limit its turn in a quarter 35

back in combination of said bolt, with body machining for this purpose. Said rotation only needs a force of action in one direction by means of the key (9), returning this to its initial position by the result of the spring (1). Inside the main cylinder (2), we mount the plunger (8) next to its 5 spring (7), said plunger (8) can rotate freely and also has a limited longitudinal path within (2), this path is limited by the shape of the key (9) in combination with the closing stop (92) always returning to its initial point when the key (9) does not act in the system, by means of the spring (7). Therefore, by introducing (9) into (8), the latter is dragged longitudinally to a position defined by (9), which in combination with a quarter turn, makes it possible to concentrically match the holes that have the pieces (2, 8 and 10) are arranged, thus leaving the system the correct reading location.

To understand this combination of linear movement and rotation, we will focus on Figure 4, which shows the key (9), on the one hand we have the shape (901), which limits the longitudinal stroke by of the closing stop (92). 20 We have the shape (902), which allows the drag of the plunger (8) in 360º. We have the shape (903), which limits the longitudinal thrust of the plunger (8), to its defined position by means of (901). We have the shape (904), which allows facing the cylinder (2) and its 90º turn. We have position (905), 25 which mentions the reading notches with the depths established for the longitudinal displacement of the readers.

In summary, if the key is not correct, the holes of the pieces (2, 8 and 10) will not be aligned, and therefore the hidden readers will not be activated to read the key 30, the system it will not work.

In figure 5, we see the assembly arrangement of the hidden reader system (16,17,18), which pass through the movable buffer (13) through the holes arranged for this case. On the back of the hidden readers (16,17,18), we ride 35

the respective springs (19), which allow by the force of understanding them, that the readers are displaced next to the buffer (13) as long as the conditions mentioned in the previous points for this purpose are met.

In the movable buffer (13), we mount the hidden security and blocking reader (14), which we fix by means of the threaded spike (15), which gives the invention another immunity element, when trying to violate the system with an unsuitable key. For this system to have an effect, the synchronism between the blocking reader (14) and the 10 key (20) must be understood, which are moved together by means of the buffer (13) and causing the immobilization of the secondary cylinder (28). ), when the key does not read correctly the notch (905) corresponding to the lock reader (14).

In figure 6, we see how to proceed to the union of the main body 15 (10), with the secondary body (21), by means of the screws (22).

In figure 7, in the upper part of the body (21), we assemble the rearmament system, composed of the bolt (23) and the spring (24), and in the lower part of the body (21), we assemble the system of 20 opening, consisting of bolt (26) and spring (25). Both systems are operated by the secondary cylinder (28) and we will see below, its operation in detail.

To understand both systems we must look at Figure 8, which shows an isometric view of the main body (10) and secondary (21) along with the secondary cylinder (28). In this view we see the correct angular assembly of the secondary cylinder (28) fixing and limiting its transverse movement by means of the screw (27) which is introduced into a circular race for this purpose, with the pin (34) inserted in the secondary cylinder 30 (28) we limit its angular rotation. At the rear we introduce its torsion spring (29), housed on one side in the body (21) with machining for this purpose, and on the other hand to a regatta of the same secondary cylinder (28). The spring (29), has the effect of getting enough torque to displace the

reset bolt (23) and the opening bolt (26), as long as the hidden readers correctly read the key, thus defining the exact longitudinal point that will make it possible to release and turn said secondary cylinder (28).

By entering the correct key and aligning the holes of the 5 elements (10) (2) (8), leaving the hidden readers (16) (17) (18), and reading the notches of the key, the opposite ends of the readers align (previous closing system), thus releasing the secondary cylinder (28), which by action of (29), rotates the bolt (26) of the opening system. In the event that the key is not correct and we have been able to operate the system, the readers' ends will not be aligned, so that the cylinder (28) will remain locked, preventing its rotation.

If we manage to operate the system by means of a modified key, or elements used for this purpose such as 15 picks, levers, etc., causing the readers (16) (17) (18) to exit, so that the cylinder is released secondary (28), the rear closure system formed by the elements (13) (14) (20) will be activated, producing a non-established longitudinal displacement, whereby the end 20 of the key (20) will be introduced into the regatta of the secondary cylinder (28), being this blocked, not allowing its rotation, nor the opening drive (26).

In figure 9 we show the assembly of the piece (33) in the housing of the body (10), and then the bolt (31) on our 25 piece (33). We mount the bolts (30) on the holes of (21), finally we proceed to the assembly of the spring (32), on the bolts (30) and (31). This system produces the same result as the wrench automatically releasing the bolt (26), but manually from inside the house. 30

In figure 10 we continue with the assembly of the piece (39) on the body (10) in the indicated housing and fixed by means of the pins (35). The pieces (36), (37) are introduced in (38) and all

this group in turn is introduced in (39) being fixed by means of the ring (40), allowing the rotation of the whole assembly.

In figure 11 we will proceed to assemble the lower reame guide for this we assemble the pieces (43) and (44) on the housing of (42), said assembly is introduced into the grooves for this purpose that are mechanized bodies (10) and (21). Then we introduce the bolts (41) through the guides (44), joining this with the movable buffer (13) and thus being linked in the horizontal displacement that occurs. 10

We continue with the assembly of the rearmament system and for this we look at Figure 12. We introduce the upper guide (45) in the mechanized groove of the body (10), we introduce the spring (47) and bolt (48) over the hole of the upper guide (45) and on the fixed block (49), said block is fixed by means of the pin (46) 15 on the body (21).

Brief description of the reset operation described.

We introduce the key (9) and turn 90º aligning all the drills as we have described previously in detail. This turn activates (3) that releases the hole of the second key of the system 20 and also activates (12) that leaves the lower guide (42) free. The readers read the key and the opening system is activated (26). At this time we can enter the second key and turn to open the locking latch. It is at this time that we can open the door, once the upper guide 25 (45) is opened, it is activated by means of the spring (47) causing it to exit. When leaving (45), it rotates the pivot system (38) in the opposite direction and this in turn introduces the lower guide (42). When entering (42) it pushes the set formed by (41) and (13), (13) it pushes the readers (16) (17) (18) to introduce them in (28) 30, but at this moment they cannot yet enter in its housing given that (28) has not yet reached its initial angular potion, by means of the spring (43) the displacement of the wait is absorbed to obtain and allow time (28) to reach its initial position.

With this movement, we also managed to push the rearmament system (23), which rotates (28) to the commented starting position, once positioned it is at this time that the readers (16) (17) (18) enter the secondary cylinder (28) blocking the system again and activating the bolt (26). 5

In Figure 13 we can see the assembly of the components that form the locking latch.

In the main body of the locking latch (51) we introduce the trigger (52) which always keeps a fixed position by means of the springs (53). At rest, the trigger (52) is locked by means of the bolt (26), so that when it is released it gives way to move the locking latch and open the door.

When we close the door, the latch (51) automatically comes out activated by means of the spring (61) and the bolt (26) will slide along the length of (52) until it reaches the end of the path by entering the gap between (51) ) and (52). At the same time (52) it will be actuated by means of the springs (53) and will prevent the movement of the latch (51) until the bolt (26) is not removed. The centers (54) manage to have the springs (53) in 20 position, the cover (55) is responsible for closing the entire system by means of the screws (56).

In figure 14 we continue with the assembly of the latch system. For this we mount the rack (58) by means of the 25 screws (57). We introduce the latch with the previous pre-assembly inside the body (59) of the lock, helping us through the guides of the body (60), we introduce the spring (61) into the latch housing (51) enabled for it, at the same time we place the bolt (62) which serves as a guide for the spring (61) 30 said bolt is fixed to the body by means of the screw (63).

In figure 15, we see in detail the assembly of the opening mechanism and how it is fixed to the body (59) by means of the screws (64). 35

In figure 16 we assemble the bushing (65) in the body (59) and fix it by means of the screws (66).

In Figure 17 we assemble the bushing (67) and join it with the gear (68), by means of the screws (69) and 5 we introduce the whole assembly into the bushing (65).

In figure 18 we perform the assembly of the ratchet system, which locks or unlocks the gear (68). For this we attach the block (71) to the body of the lock (59), using the screws (70). We mount the stopper pin (72) on the block (71), which acts as a stopper for the hook (76). We mount the centering pin (74) on the block (71) and then concentric to it the spring (73), which is embedded in the body (59), producing the return of the trigger (76), when actuated. We mount the trigger (76), against the block (71), by means of the adjustment screw (75), 15 which supports the same trigger in a fixed position but at the same time allows it to rotate on it.

In figure 19 we carry out the assembly of the slip system, which has the mission of disconnecting or connecting the ratchet when the door is opened or closed. We mount the guide (79) on the body (59) by means of the screws (77), we mount the slip (80) inside the guide (79). The thrust bolt (78) is inserted into the slide housing (80). Said bolt is responsible for pushing the trigger (76), when the door is opened or closed, locking or releasing the gear (68). 25

In figure 20 we assemble the body closing system, for this we connect the bushing (82) with the housing (97), using the screws (83), finally we pre-assemble the separator (81) in the gear housing (68), and we close the whole set with the body (59), by the means established for such purpose.

In figure 21 we carry out the assembly of the manual opening system from inside the house. On the one hand it includes the unlocking of the bolt (26) and on the other hand the manual movement of the latch (51). The shaft (84) transmits the opening movement of the 35

bolt (26) and the shaft (86) is responsible for moving the latch (51) manually and guided by means of the coliseum housed in the cover (87), and by means of the key (85) integral with the shaft (86) . The screws (88), close the system once threaded to the trim cover (93). The piece (89) acts as a trim means 5 to cover the screws (88), and the knobs (90, 91) are threaded to the shafts (84) and (86), to facilitate the ergonomics of the system itself.

In figure 22 we perform the assembly of the clearance compensation system. For this, we mount the thicknesses (96) butt against the frame (95), by means of cylindrical pins. The thicknesses (96), are in continuous thrust by means of two springs housed inside. With this system we ensure that slips (45) and (80), work perfectly adjusted and there are no problems of play between frame and door. fifteen

In figure 23 we perform the assembly of the exterior trim system and stops. For this, we pre-mount the stops (92) and (94), by means of their adjustment diameters, in the housings destined for this purpose, then we proceed to mount the outer bezel which closes the system by means of screws 20 (88 ).

Annex 1, Open Door:

According to figure 24, detail of the mechanism when the door is open, we find the following situation and state of the system. The main cylinder (2) is in its initial position 25 (the holes misaligned at 90 degrees to the readers) and the bolt (12) that blocks the lower guide (42) is activated. The springs (19) are compressed, the readers (16) are inside the secondary cylinder (28), blocking it. The spring (43) is in the rest position, pushing the slide 30 (44) on the lower guide (42). The pivots (36) inserted on the disc (38) are in contact with (42) and (45).

Annex 2, Closed Door:

According to figure 25, detail of the mechanism when the door is closed, the upper guide (45) is inserted, compressing the spring (47), the pivot (36) is separated from the upper guide (45), the rest of the system remains still.

Annex 3, We introduce and turn key: 5

According to figure 26, detail of the mechanism when the key is inserted and turned. The situation of the mechanism when the key is introduced and turned 90º is as follows. We rotate the main body (2), 90º, deactivating the bolt (12), which releases the lower guide (42). In turn, all the holes of the 10 readers (16) are aligned, the springs (19) that were compressed push the readers (16), which read the key. The readers (16) in their displacement drag the movable buffer (13), which in turn also draws the slider (44) and is in turn the lower guide (42). The displacement of the lower guide (42) causes 15 to push the pivot (36) which in turn rotates the disc (38) integral thereto, rearming the system, the pivots (36) being in contact with the lower guide ( 42) and the upper guide (45). When reading the correct key, the readers (16) are aligned, releasing the secondary cylinder (28), which by effect of the torsion spring activates the opening system. With the displacement of the lower guide (42), the bolt (23) is deactivated by disconnecting the rearmament system, allowing the rotation of the secondary cylinder (28), this is when we can open the door. When opening the door we return to the starting point “Door 25 Open”, whereby the upper guide (45) would come out of the spring (47), the upper guide (45) rotates the disc (38) which in turn pushes the lower guide (42) next to the spring (43) and the slide (44), the latter drags the movable buffer (13) that at the same time drags and tries to introduce the readers (16) into the secondary cylinder (28), but it cannot, because (28) is misaligned, it is at this time that we compress the spring (43) to gain enough angular stroke until the alignment between the readers (16) and the secondary cylinder (28) is achieved. As the lower guide (42) is introduced, push 35

bolt (23) that simultaneously rotates the secondary cylinder (28), until the readers are aligned with it. Upon leaving the readers of the main cylinder (2), it is released and, as a result of the torsion spring, rotates 90º returning to its initial position, pushing the bolt (12) to block the lower guide (42), 5 leaving the system rearmed, being able to remove the key.

Claims (7)

1. High security Mechanical Lock characterized in that it comprises a hidden and inaccessible reading system, actuated by linear movement and a quarter turn, with 5 rearmament and automatic closing. 2. High security Mechanical Lock according to claim 1, characterized in that the main opening system is composed of a key (9) which by means of lateral notches (905) and established shapes (901,902,903,904) for this, allows defining a point linear and angular at 90º, to give way to the liberation of the readers (16,17,18), the minimum defined number will be one and maximum available space, which allow the release of the secondary cylinder (28), which unlocks the bolts (23) and (26), thus being able to proceed to the opening of the upper guide (45) and the locking latch (51). 3. High security Mechanical Lock according to claim 2, characterized in that the reader system (16,17,18) is never exposed to be violated or manipulated. In the case of being able to face the main cylinder (2) and the plunger (8), in the correct reading position, a fourth security reader (14) would come out which, not reading the correct key, produces a displacement of the key (20), leaving the mechanism 25 locked by means of it. 4. High security Mechanical Lock according to claims 2/3, characterized in that the system automatically rearms when the door is opened, since the upper guide (45) pushed by the spring (47), rotates the disk (38) , which in turn pushes the lower guide (42) next to the spring (43) and the slide (44), dragging the movable buffer (13), which in turn introduces the readers into the secondary cylinder (28). The main cylinder (2) is releases, returning to its initial potion, being able to remove the key (9). 5. High security Mechanical Lock according to any of the preceding claims, characterized in that the system is composed of an automatic opening of the locking latch 5 (51), by means of the gear (68), and which will only be accessible if the key (9) has enabled the bolt unlocking system (3). Said locking latch (51) is prepared to be able to operate other locking systems in the same door both in its upper and lower part. 10 6. High security Mechanical Lock according to any of the preceding claims, characterized in that the system complies with the manual means to act from inside the housing, being able to release the bolt stop (26), by means of the activation of the shaft (31 ), which pivots by the force 15 exerted on the hub (33), by means of the shaft (84), activated by the knob (91). Similarly, the locking latch (51) can be activated through the shaft (86), acting on the knob (90). 7. High security Mechanical Lock according to any of the previous 20 claims, characterized in that the system is provided with floating elements for the elimination of games between the housing frame and the lock system by means of the parts (96).  25  30